DeePKS-kit is a program to generate accurate energy functionals for quantum chemistry systems, for both perturbative scheme (DeePHF) and self-consistent scheme (DeePKS).
The program provides a command line interface deepks
that contains five sub-commands,
train
: train an neural network based post-HF energy functional modeltest
: test the post-HF model with given data and show statisticsscf
: run self-consistent field calculation with given energy modelstats
: collect and print statistics of the SCF the resultsiterate
: iteratively train an self-consistent model by combining four commands above
DeePKS-kit is a pure python library so it can be installed following the standard git clone
then pip install
procedure. Note that the two main requirements pytorch
and pyscf
will not be installed automatically so you will need to install them manually in advance. Below is a more detailed instruction that includes installing the required libraries in the environment.
We use conda
here as an example. So first you may need to install Anaconda or Miniconda.
To reduce the possibility of library conflicts, we suggest create a new environment (named deepks
) with basic dependencies installed (optional):
conda create -n deepks numpy scipy h5py ruamel.yaml paramiko
conda activate deepks
Now you are in the new environment called deepks
.
Next, install PyTorch
# assuming a GPU with cudatoolkit 10.2 support
conda install pytorch cudatoolkit=10.2 -c pytorch
and PySCF.
# the conda package does not support python >= 3.8 so we use pip
pip install pyscf
Once the environment has been setup properly, using pip to install DeePKS-kit:
pip install git+https://github.com/deepmodeling/deepks-kit/
An relatively detailed decrisption of the deepks-kit
library can be found in here. Please also refer to the reference for the description of methods.
Please see examples
folder for the usage of deepks-kit
library. A detailed example with executable data for single water molecules can be found here. A more complicated one for training water clusters can be found here.
Check this input file for detailed explanation for possible input parameters, and also this one if you would like to run on local machine instead of using Slurm scheduler.
[1] Chen, Y., Zhang, L., Wang, H. and E, W., 2020. Ground State Energy Functional with Hartree–Fock Efficiency and Chemical Accuracy. The Journal of Physical Chemistry A, 124(35), pp.7155-7165.
[2] Chen, Y., Zhang, L., Wang, H. and E, W., 2021. DeePKS: A Comprehensive Data-Driven Approach toward Chemically Accurate Density Functional Theory. Journal of Chemical Theory and Computation, 17(1), pp.170–181.